Steam-hydrocarbon reforming process

We claim: 1. A steam-hydrocarbon reforming process comprising: passing a feed stream to a first reactor containing a catalyst during a first period, reacting the feed stream in the first reactor in the presence of the catalyst under reaction conditions sufficient to react the feed stream and form an intermediate product stream, and withdrawing the intermediate product stream from the first reactor; wherein the feed stream comprises steam and hydrocarbons including C2+ hydrocarbons, wherein the concentration of the C2+ hydrocarbons in the feed stream varies during the first period; wherein the feed stream has a molar flow rate of hydrocarbons, F HC ; and wherein the feed stream has a molar flow rate of steam, F S , thereby defining a ratio, F S /F HC , of the molar flow rate of steam to the molar flow rate of hydrocarbons in the feed stream; dividing the intermediate product stream into a first portion and a second portion, the second portion of the intermediate product stream having a mass flow rate, M 1 ; introducing a second reactor feed stream comprising the first portion of the intermediate product stream into a second reactor, reacting the second reactor feed stream in the second reactor in the presence of a second catalyst under reaction conditions effective to form a reformate comprising H 2 , CO, CH 4 , and H 2 O, and withdrawing the reformate from the second reactor; conditioning the second portion to remove at least water and ammonia and form a conditioned portion of the second portion of the intermediate product stream; measuring a C2+ hydrocarbon content in the conditioned portion of the second portion of the intermediate product stream in a chemical component analyzer; increasing the ratio of the molar flow rate of steam to the molar flow rate of hydrocarbons in the feed stream responsive to the step of measuring the C2+ hydrocarbon content when the C2+ hydrocarbon content equals or exceeds an upper target C2+ hydrocarbon content during the first period; and decreasing the ratio of the molar flow rate of steam to the molar flow rate of hydrocarbons in the feed stream responsive to the step of measuring the C2+ hydrocarbon content when the C2+ hydrocarbon content equals or drops below a lower target C2+ hydrocarbon content during the first period. 2. The process of claim 1 wherein the second reactor feed stream is introduced into a plurality of catalyst-containing reformer tubes in the second reactor, and wherein the reformate is withdrawn from the plurality of catalyst-containing reformer tubes, the process further comprising: combusting a fuel with an oxidant gas in a combustion section of the second reactor external to the plurality of catalyst-containing reformer tubes under conditions effective to combust the fuel to form a combustion product gas and generate heat to supply energy for reacting the second reactor feed stream inside the plurality of catalyst-containing reformer tubes, and withdrawing the combustion product gas from the combustion section. 3. The process of claim 1 wherein the step of conditioning comprises: removing water from the second portion of the intermediate product stream by condensation to form a water-depleted portion of the second portion of the intermediate product stream; removing ammonia from the water-depleted portion of the second portion of the intermediate product stream thereby forming an ammonia-depleted portion of the second portion of the intermediate product stream; and passing the ammonia-depleted portion to a dryer to remove water and form a dried portion of the second portion of the intermediate product stream, the dried portion of the second portion having a mass flow rate, M d ; wherein the conditioned portion of the second portion of the intermediate product stream comprises at least a portion of the dried portion. 4. The process of claim 3 wherein the dryer is a membrane dryer. 5. The process of claim 3 wherein M d ≦0.20×M 1 . 6. The process of claim 1 further comprising: monitoring the C2+ hydrocarbon content in the conditioned portion as a function of the molar flow rate of steam, F s , and the molar flow rate of hydrocarbons, F HC , in the feed stream; and assessing whether to replace the catalyst in the first reactor responsive to the step of monitoring; wherein during a second period after the first period, the process comprises replacing the catalyst in the first reactor responsive to the step of assessing whether to replace the catalyst in the first reactor. 7. The process of claim 1 further comprising: evaluating the activity of the catalyst in the first reactor by assessing the response of the measured C2+ hydrocarbon content in the conditioned portion to the step of increasing the ratio of the molar flow rate of steam, F s , to the molar flow rate of hydrocarbons, F HC , in the feed stream; and wherein during a second period after the first period, the process comprises replacing the catalyst in the first reactor responsive to the step of evaluating the activity of the catalyst in the first reactor. 8. The process of claim 1 wherein the chemical component analyzer is a gas chromatograph. 9. The process of claim 1 further comprising: separating the reformate by pressure swing adsorption to produce a hydrogen-containing product and a by-product gas. 10. The process of claim 9 further comprising: pretreating a feedstock comprising hydrocarbons including C2+ hydrocarbons by hydrogenation and/or hydrodesulphurization; mixing steam with the pretreated feedstock to form the feed stream to the first reactor; and supplying at least a portion of the hydrogen-containing product for the pretreatment of the feedstock. 11. The process of claim 1 further comprising: pretreating a feedstock comprising hydrocarbons including C2+ hydrocarbons by hydrogenation and/or hydrodesulphurization; and mixing steam with the pretreated feedstock to form the feed stream to the first reactor. 12. The process of claim 1 further comprising: increasing the ratio of the molar flow rate of steam to the molar flow rate of hydrocarbons in the feed stream responsive to the step of measuring the C2+ hydrocarbon content; measuring the C2+ hydrocarbon content in the conditioned portion while reacting the feed stream with the increased ratio in the first reactor; comparing the measured C2+ hydrocarbon content with an allowable content value representative for the C2+ hydrocarbon content in the conditioned portion ( 85 ) at the increased ratio of the molar flow rate of steam to the molar flow rate of hydrocarbons; and replacing the catalyst in the first reactor if the measured C2+ hydrocarbon content is greater than the allowable content value. 13. The process of claim 1 wherein the step of conditioning comprises: cooling the second portion in a heat exchanger of the intermediate product stream to condense water from the second portion thereby forming a liquid fraction and a vapor fraction; dividing the cooled second portion into a water-depleted vapor fraction-enriched portion having a time-averaged mass flow rate, F 1 , and a liquid fraction-enriched portion having a time-averaged mass flow rate, F 2 ; and removing at least water and ammonia from the water-depleted vapor fraction-enriched portion to form the conditioned portion; wherein F 1 and F 2 are controlled such that 0 < F 1 F 1